US20090077875A1

US20090077875A1 - System for conditioning crops

Info

Publication number: US20090077875A1
Application number: US12/092,340
Authority: US
Inventors: Lucienne Jozefina Wilhelmina Maria Krosse; Nicolaas Richardus Bootsveld
Original assignee: Nederlandse Organisatie voor Toegepast Natuurwetenschappelijk Onderzoek TNO
Current assignee: Nederlandse Organisatie voor Toegepast Natuurwetenschappelijk Onderzoek TNO
Priority date: 2005-11-02
Filing date: 2006-11-02
Publication date: 2009-03-26
Also published as: WO2007053011A1; EP1945020B1; ES2437579T3; US8051602B2; EP1945020A1; EP1782684A1

Abstract

System for conditioning crops e.g. in a greenhouse, comprising climate control means which are arranged for providing a local microclimate area around the relevant crop, which climate control means comprising first means at a first location close to the crop, which are arranged for local humidification and simultaneous cooling or heating the local microclimate area, as well as second means at a second location close to the crop, which are arranged for dehumidification and simultaneous cooling or heating the local microclimate area.

Description

FIELD

The invention refers to a system for conditioning—providing for a good climate—crops e.g. in a greenhouse.

BACKGROUND

Greenhouses have been developed and introduced in the Netherlands for three reasons: 1) to be able to cultivate crops that can not be cultivated in the Dutch climate, 2) to give a longer cultivation season to full land crops, 3) to be able to guarantee a more controllable quality. The conditioning of the greenhouse is essential: temperature, atmospheric humidity and CO2 concentration determine, together with the supply of light, the quality and quantity of a crop. Because of the different requirements regarding the indoor climate, per crop considerable differences in the applied fitting techniques are possible.
Basic equipment consists of the central generation of heat and CO2 by means of boilers. The heat is distributed through pipes, which also serve the internal transport system. Moisture is brought in by the crop and provides in summer for the cooling of the greenhouse, combined with the ventilation through the opening of the windows. Ventilators suspended from the greenhouse construction provide here for a better distribution of the conditions. In addition to the use of energy of the ventilators, this has also consequences for the greenhouse construction. The greenhouse construction must be carried out heavier (and thus more expensive), because it also serves as supporting construction for the ventilators and the windows to be opened.
At the moment, it is not possible to operate/control the temperature, atmospheric humidity and CO2 concentration independently from one another. Dehumidification of the greenhouse takes for example place by simply opening windows. The greenhouse is herewith not only de-moisturized, but the CO2 also disappears and the optimal greenhouse temperature gets disturbed. An additional disadvantage is the possible contamination from the surroundings (insects, diseases, etc.).
In modern greenhouse farming the “Innogrow” concept is generally known. In this concept the air is demoisturized by first cooling it and then partially heating it again. The cool, dry air is distributed by large textile hoses under the crop. A direct result is that enormous quantities of air have to be moved by means of ventilators. The length of the production line is furthermore limited, because a larger production line requires the air hose to have a larger diameter. The tendency goes towards production lines that are as long as possible. The generation of cold and heat takes place by means of heat pumps and storage of energy in the soil. It is important that the concept consists of a heat surplus and that it can only be realized by placing a conventional greenhouse adjacent to it.

SUMMARY

The invention aims to present an improved system for conditioning crops e.g. in a greenhouse, comprising climate control means which are arranged for providing a local microclimate area around the relevant crop, which climate control means comprise first means at a first location with regard to the crop, which are arranged for local humidification and simultaneous cooling or heating the local microclimate area, as well as second means at a second location with regard to the crop, which are arranged for dehumidification and simultaneous cooling or heating the local microclimate area.
An aspect of the invention is to provide a system for conditioning crops e.g. in a greenhouse comprising climate control means which are arranged for providing a local microclimate area around the relevant crop, which climate control means comprise first means at a first location close to the crop, which are arranged for local humidification and simultaneous cooling or heating the local microclimate area, as well as second means at a second location close to the crop, which are arranged for dehumidification and simultaneous coding or heating the local microclimate area, said first means comprising one or more vapor outlets which are arranged to create a foggy or vaporous climate around the relevant crop in the local microclimate area, said one or more vapor outlets being connected with third means which are arranged to provide that the relevant vapor outlets remain in line with the growing level of the crops, said second means comprising a duct system which is arranged to guide a hygroscopic liquid flow, which duct system and hygroscopic liquid flow are arranged to absorb and remove either moisture surplus or heat surplus or both from the local microclimate area, said duct system comprising one or more hoses or tubes which are porous or permeable for water vapor, wherein the first means and second means being located at mainly opposite locations with regard to the crop.
One important aspect of the present invention is that lowering down the temperature in a greenhouse by means of evaporation of liquid (water) only has been possible by making use of the gap between the actual relative moisture and the maximum admissible moisture. In other words, this only can be applied at dry climate circumstances, e.g. in the south of Spain or in Arizona (US). In the present inventive configuration those dry circumstances—needed for said cooling effect of evaporating water—are created deliberately. Those dry circumstances are created by abstracting moisture and heat at one side of the crops, e.g. at the bottom level of the greenhouse, viz. by means of the second means, operating e.g. under the crops, thus enabling a good cooling performance of the first means, operating at the other side of the crops, e.g. at the top-of-the-crop level.
It is noted that in general it is sufficient to have the first means and the second means located in the neighbourhood of the crop, to provide a microclimate around it. It may be preferred that the first means and second means are located at mainly opposite locations with regard to the crop. It may be even more preferred to have the first means located mainly at the top of the crop and the second means mainly at the bottom side—or even under—of the crop.
Preferably, said first means may comprise one or more vapor outlets—e.g. a vapor nozzle or (e.g. ultrasonic) vapor pad—which are arranged to create a foggy or vaporous climate around the relevant crop in the local microclimate area. To realize that the first means are always operating in line with the grow level of the crop, the vapor outlets preferably are connected with third means which are arranged to provide that the relevant vapor outlets remain in line with the growing level of the crops.
Preferably the second means are arranged for local dehumidification and simultaneous cooling or heating the local microclimate area.
The second means preferably comprise a duct system which is arranged to guide a hygroscopic liquid flow, which duct system and hygroscopic liquid flow are arranged to absorb and remove either moisture surplus or heat surplus or both from the local microclimate area. The duct system may comprise hoses or tubes which are porous or permeable for water vapor, without letting through the hygroscopic liquid, flowing through them. The duct system may, alternatively, comprise an open channel system.
Besides for dehumidification—resulting in the desired dry climate which is a “conditio sine qua non” for simultaneous cooling the microclimate areas during—and due to—humidification (by spraying or vaporizing water) performed by the first means, the second means may additionally be arranged for local humidification and simultaneous cooling or heating the local microclimate area, by which measure the moisture and temperature control dynamics can even be improved.
Fourth means may be arranged to control the degree of dehumidification or humidification by varying either the concentration or the temperature of the hygroscopic liquid or both, while fifth means may be arranged to regenerate the hygroscopic liquid.
Features of the new concept are:

- Local conditioning at the crop
- Separation of the functions heating, cooling, humidification, dehumidification and CO2 fertilization
- Transport of heat and moisture with hygroscopic liquids instead of air
- Semi-closed greenhouse
- Withdrawal of heat with hygroscopic liquids (large heat content, mC_p, many times larger than heat content of air)

The invention is discussed further below using some illustrative figures.

EXEMPLARY EMBODIMENT

FIG. 1 and FIG. 2 together show an embodiment of the present invention

FIGS. 3 a, 3 b and 3 c show different embodiment details, viz. alternative locations of the first and second means, providing the microclimate around the crops.

FIGS. 1 and 2 show a system for conditioning crops 2 in a greenhouse 1, comprising climate control means 4-8 which are arranged for providing a local microclimate area 3 around the crop. The climate control means comprise first means 4 which are located at the top of the crop 2 and which are arranged for local humidification 5 and simultaneous cooling—or heating—the local microclimate area 3, as well as second means 6-7 which are located under the crop and which are arranged for local dehumidification 7 a and simultaneous cooling or heating the local microclimate area.
In FIG. 1 the first means formed by vapor outlets 4 which are arranged to create a foggy or vaporous climate 5 around the crop in the local microclimate area 3. The vapor outlets 4 may be mounted on third means, e.g. a vertically movable frame—e.g. controlled by servo motors and a greenhouse computer system—, arranged to provide that the vapor outlets 4 remains in line with the growing level of the crops 2
In the embodiment of FIG. 1 the second means comprise a duct system 6, arranged to guide a hygroscopic liquid flow 7, which duct system 6 and hygroscopic liquid flow 7 are arranged to absorb 7 a and remove either moisture surplus or heat surplus or both from the local microclimate area. The duct system may contain hoses or tubes 6 made of a material which is porous or permeable for water vapor, thus enabling said moisture absorption 7 a. As an alternative the duct system could comprise open channels.
Alternatively, the second means comprise a local heat exchanger placed close to a crop for local dehumidification of the local microclimate of the crop.
The second means 6-7 may—if necessary—additionally be arranged for local humidification and simultaneous cooling or heating the local microclimate area, viz. by varying—by means of fourth means 8 (FIG. 2)—either the concentration or the temperature of the hygroscopic liquid or both. Those means 8 could additionally be to regenerate the hygroscopic liquid.
In the embodiment shown in FIGS. 1 and 2 a microclimate is created by humidification, cooling or—if necessary—heating at the top of the crop 2 and by dehumidification—or, if necessary, humidification, cooling or heating—under the crop. A preferred embodiment for the humidification and cooling at the same time can be by putting at the top of crop a frame of vapor outlets 4 through which a fog 5 can be created. On the one hand the air becomes moisturized in this way, on the other hand the fog drops evaporate into the air around the crop, so that it gets cooled.
The necessary dehumidification then takes place under the crop. The hygroscopic liquid flowing through the ducts 6 provide that the moisture gets absorbed 7 a and removed to the regenerator/heater 8. Besides porous hoses or open ducts, a system may be used with membrane contactors. The degree of dehumidification can be regulated by varying both the concentration and the temperature of the hygroscopic liquid in module 8.
During the dehumidification 7 a, heat is created. This heat is removed directly by means of the hygroscopic liquid flow. This removal of moisture and heat by means of a liquid flow 7 is many times more effective than e.g. removal by air: smaller flows, less volume and less energy are needed.
For regeneration and—if desired—heating of the hygroscopic liquid 7 in module 8 different sources may be used, e.g. gas, rest heat or renewable sources.
An additional advantage of the local dehumidification by means of a hygroscopic liquid is that the same system can be used for humidification too. For this, the concentration of the hygroscopic liquid can be varied (“conc.”) in module 8.
In the dehumidification state the hygroscopic fluid flows with a low degree of moisture load through the ducts 6 which are pervious to vapor. Because of the difference in partial water vapor pressure between the greenhouse 1 and the hygroscopic fluid, the water vapor flows from the greenhouse to this hygroscopic fluid, after which it gets absorbed.
In the humidification state the hygroscopic fluid flows with a high degree of moisture load through the porous ducts 6. In this case the partial water vapor pressure above the hygroscopic fluid is just higher than in the greenhouse 1, by which moisture will evaporate from the hygroscopic fluid to the greenhouse, thus moisturizing the greenhouse. By, among other things, the choice of the hygroscopic fluid, the degree of moisture load and the temperature of the liquid, the humidity in the greenhouse can be kept at a certain constant level.
FIGS. 3 a, 3 b and 3 c show different locations of the first means 4 and second means 6, providing together the microclimate 3 around the crops 2. FIG. 3 a is a cross-sectional view of the embodiments shown in FIG. 1, comprising a vapor outlet 4 close to the top of the crop 2, while a duct 6 extends under a row of crops 2. In FIG. 3 b fog environment 5 is generated by a vapor outlet 4 which located at one side of the crop 2, while the duct 6—guiding a hygroscopic fluid flow—extends along the crop 2 at the other side, thus providing the desired microclimate around the crop 2. Finally, in FIG. 3 c both, the first means 4 and the second means 6 are located around the bottom side of the crop 2. Which locations for the first and second means are preferred may depend on the grow characteristics of the relevant crops e.g. with regard to the location of the microclimate area.
Advantages of the new configuration compared to prior art technology are:

- Less volume needed because of the larger heat content per volume unit of liquids compared to air.
- Increased incidence of light; fewer heavy window constructions and ventilators in the roof of the greenhouse that take away light. In this way, the production yields will increase.
  - In the absence of windows that can be opened and the absence of large ventilators, lighter and cheaper greenhouse constructions become possible.
  - Less use of energy and thus reduction of costs of production (a very large part of the costs in greenhouse farming are costs due to use of energy).
  - No windows need to be opened to transport the moisture, which on the one hand minimizes the risk of contamination from the open air (insects, diseases, etc.). On the other hand, it is possible in this way to maintain the CO2 concentration in the greenhouse at an higher level, which will increase the yields.

Claims

1. System for conditioning crops e.g. in a greenhouse, comprising climate control means which are arranged for providing a local microclimate area around the relevant crop, which climate control means comprise first means at a first location close to the crop, which are arranged for local humidification and simultaneous cooling or heating the local microclimate area, as well as second means at a second location close to the crop, which are arranged for dehumidification and simultaneous cooling or heating the local microclimate area, said first means comprising one or more vapor outlets which are arranged to create a foggy or vaporous climate around the relevant crop in the local microclimate area, said one or more vapor outlets being connected with third means which are arranged to provide that the relevant vapor outlets remains in line with the growing level of the crops, said second means comprising a duct system which is arranged to guide a hygroscopic liquid flow, which duct system and hygroscopic liquid flow are arranged to absorb and remove either moisture surplus or heat surplus or both from the local microclimate area, said duct system comprising one or more hoses or tubes which are porous or permeable for water vapor, the first means and second means being located at mainly opposite locations with regard to the crop.

2. System for conditioning crops e.g. in a greenhouse, comprising climate control means which are arranged for providing a local microclimate area around the relevant crop, which climate control means comprise first means at a first location close to the crop, which are arranged for local humidification and simultaneous cooling or heating the local microclimate area, as well as second means at a second location close to the crop, which are arranged for dehumidification and simultaneous cooling or heating the local microclimate area.

3. System according to claim 2, wherein the second means at a second location close to the crop are arranged for local dehumidification and simultaneous cooling or heating the local microclimate area.

4. System according to claim 2, said first means comprising one or more vapor outlets which are arranged to create a foggy or vaporous climate around the relevant crop in the local microclimate area.

5. System according to claim 2, said one or more vapor outlets being connected with third means which are arranged to provide that the relevant vapor outlets remains in line with the growing level of the crops.

6. System according to claim 2, said second means comprising a duct system which is arranged to guide a hygroscopic liquid flow, which duct system and hygroscopic liquid flow are arranged to absorb and remove either moisture surplus or heat surplus or both from the local microclimate area.

7. System according to claim 6, said duct system comprising one or more hoses or tubes which are porous or permeable for water vapor.

8. System according to claim 1, said duct system comprising an open channel system.

9. System according to claim 1, said second means are additionally arranged for local humidification and simultaneous cooling or heating the local microclimate area.

10. System according to claim 6, comprising fourth means, which are arranged to control the degree of dehumidification or humidification by varying either the concentration or the temperature of the hygroscopic liquid or both.

11. System according to claim 1, comprising fifth means, which are arranged to regenerate the hygroscopic liquid.

12. System according to claim 2, the first means and second means being located at mainly opposite locations with regard to the crop.

13. System according to claim 1, the first means being located mainly at the top of the crop and the second means being located mainly at the bottom side of the crop.